Related papers: Seasonal Fire Prediction using Spatio-Temporal Deep Neural Networks

Seasonal Fire Prediction using Spatio-Temporal Deep Neural Networks

URL: http://arxiv.org/abs/2404.06437v1
Date: Tue, 9 Apr 2024 16:28:54 GMT
Title: Seasonal Fire Prediction using Spatio-Temporal Deep Neural Networks
Authors: Dimitrios Michail, Lefki-Ioanna Panagiotou, Charalampos Davalas, Ioannis Prapas, Spyros Kondylatos, Nikolaos Ioannis Bountos, Ioannis Papoutsis,
Abstract summary: We utilize SeasFire, a comprehensive global wildfire dataset with climate, vegetation, oceanic indices, and human-related variables, to enable seasonal wildfire forecasting with machine learning. For the predictive analysis, we train deep learning models with different architectures that capture wildfire-temporal context. Our findings demonstrate the great potential of deep learning models in seasonal fire forecasting.
Score: 2.748450182087935
License: http://creativecommons.org/licenses/by/4.0/
Abstract: With climate change expected to exacerbate fire weather conditions, the accurate anticipation of wildfires on a global scale becomes increasingly crucial for disaster mitigation. In this study, we utilize SeasFire, a comprehensive global wildfire dataset with climate, vegetation, oceanic indices, and human-related variables, to enable seasonal wildfire forecasting with machine learning. For the predictive analysis, we train deep learning models with different architectures that capture the spatio-temporal context leading to wildfires. Our investigation focuses on assessing the effectiveness of these models in predicting the presence of burned areas at varying forecasting time horizons globally, extending up to six months into the future, and on how different spatial or/and temporal context affects the performance of the models. Our findings demonstrate the great potential of deep learning models in seasonal fire forecasting; longer input time-series leads to more robust predictions across varying forecasting horizons, while integrating spatial information to capture wildfire spatio-temporal dynamics boosts performance. Finally, our results hint that in order to enhance performance at longer forecasting horizons, a larger receptive field spatially needs to be considered.

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